Neutron Stress Measurement of W/Ti Composite in Cryogenic Temperatures Using Time-of-Flight Method

IF 1.3 Q3 INSTRUMENTS & INSTRUMENTATION

Quantum Beam Science Pub Date : 2023-03-07 DOI:10.3390/qubs7010008

M. Nishida, S. Harjo, T. Kawasaki, Takayuki Yamashita, W. Gong

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Abstract

In this study, the thermal stress alterations generated in a tungsten fiber reinforced titanium composite (W/Ti composite) were evaluated by the neutron stress measurement method at cryogenic temperatures. The W/Ti composite thermal loads were repeated from room temperature to the cryogenic temperature (10 K), and alterations in thermal residual stress were evaluated using the neutron in situ stress measurement method. In this measurement, the stress alterations in the titanium matrix and the tungsten fibers were measured. This measurement was carried out by TAKUMI (MLF-BL19) of J-PARC, a neutron research facility in the Japan Atomic Agency. The measurement method of TAKUMI is the time-of-flight (TOF) method. Owing to this measurement method, the measurement time was significantly shortened compared to the angle-dispersion type measurement by a diffractometer. As a result of the measurement, large compressive stresses of about 1 GPa were generated in the tungsten fibers, and tensile stresses of about 100 MPa existed in the titanium matrix. The thermal stresses due to the temperature change between room temperature and cryogenic temperature is caused by the difference of thermal expansions between the tungsten fibers and the titanium matrix, and these stress values can be approximated by a simple elastic theory equation.

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飞行时间法测量W/Ti复合材料在低温下的中子应力

本研究采用中子应力测量法对钨纤维增强钛复合材料(W/Ti复合材料)在低温下产生的热应力变化进行了研究。从室温到低温(10 K)重复W/Ti复合材料的热载荷，并使用中子原位应力测量法评估热残余应力的变化。在此测量中，测量了钛基体和钨纤维的应力变化。这项测量是由日本原子能机构的中子研究机构J-PARC的TAKUMI (MLF-BL19)进行的。TAKUMI的测量方法是飞行时间(TOF)法。与衍射仪的角色散型测量相比，这种测量方法大大缩短了测量时间。测量结果表明，钨纤维中产生了约1 GPa的较大压应力，钛基体中存在约100 MPa的拉应力。室温和低温温度变化引起的热应力是由钨纤维和钛基体之间的热膨胀差异引起的，这些应力值可以用一个简单的弹性理论方程近似表示。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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